Multiple lens imaging apparatuses, and methods and programs for setting exposure of multiple lens imaging apparatuses

ABSTRACT

When an exposure value calculated according to a result of photometric measurement for predetermined main imaging units among a plurality of imaging units is used for setting exposure of the main imaging units and sub-imaging units other than the main imaging units, judgment is carried out as to whether an image or images obtained in photography with the sub-imaging units by setting the exposure thereof according to the exposure value is/are saturated. In the case where a result of the judgment is affirmative, any one of the sub-imaging units having obtained the saturated image or images is designated as new main imaging units. The exposure value is calculated newly, and the exposure is set for the new main imaging units and for new sub-imaging units other than the new main imaging units.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to multiple lens imaging apparatuses eachhaving a plurality of imaging units and to methods for setting exposureof the multiple lens imaging apparatuses. The present invention alsorelates to programs that cause a computer to execute the methods.

2. Description of the Related Art

Various kinds of multiple lens imaging apparatuses that enablethree-dimensional (3D) imaging or panoramic imaging have been proposedas multiple lens imaging apparatuses each having multiple imaging units.In such multiple lens imaging apparatuses, identical imaging units arelocated to the right and left of each of the apparatuses, and imagesobtained simultaneously by the respective imaging units are subjected tocomposite processing to generate a stereo image realizing stereovisionor a panoramic image.

Meanwhile, in each of multiple lens imaging apparatuses, each of imagingunits has an iris and an iris adjustment mechanism that are controlledindependently from the other imaging unit or units. Therefore, an amountof light is different between images from the respective imaging units,and a stereo image or a panoramic image generated from the images issubstantially uncomfortable to view.

For this reason, a method of determining one exposure value based oncomparison of exposure values between imaging units and a method ofdetermining one exposure value based on comparison of image dataobtained by imaging units have been proposed (see Japanese UnexaminedPatent Publication Nos. 8(1996)-029895 and 9(1997)-084056,respectively). In addition, a method has been proposed wherein luminancedata of an image obtained by a specific one of imaging units arecompared with reference data and exposure of an imaging unit other thanthe specific imaging unit is adjusted based on a result of thecomparison (see Japanese Unexamined Patent Publication No. 2000-341719).

However, in the methods described in Japanese Unexamined PatentPublication Nos. 8(1996)-029895 and 9(1997)-084056, each of the imagingunits needs to calculate the exposure value independently. Therefore,the configuration of a corresponding multiple lens imaging apparatusbecomes complex, and the apparatus becomes larger in size. In the methoddescribed in Japanese Unexamined Patent Publication No. 2000-341719, theexposure value set for one of the imaging units is used for the otherimaging unit. Therefore, a corresponding apparatus can be prevented frombecoming large in size. However, the calculated exposure value is notnecessarily appropriate for the other imaging unit. Therefore, an imageobtained by the other imaging unit may have a saturated area such as anarea where white compression or black compression is observed.

SUMMARY OF THE INVENTION

The present invention has been conceived based on consideration of theabove circumstances, and an object of the present invention is to setexposure of a multiple lens imaging apparatus to avoid generation of asaturated image as much as possible.

A first multiple lens imaging apparatus of the present invention is amultiple lens imaging apparatus having a plurality of imaging unit forobtaining images by photography, and the apparatus comprises:

exposure setting unit for using an exposure value calculated accordingto a result of photometric measurement for predetermined main imagingunit among the plurality of imaging unit, to set exposure of the mainimaging unit and sub-imaging unit other than the main imaging unit. Inthe case where an image or images obtained in photography with thesub-imaging unit by setting the exposure thereof according to theexposure value is/are saturated, the exposure setting unit designatesany one of the sub-imaging unit having obtained the saturated image orimages as new main imaging unit. The exposure setting unit then newlycalculates the exposure value and sets the exposure of the new mainimaging unit and new sub-imaging unit other than the new main imagingunit.

In this manner, the exposure value that will not cause image saturationcan be calculated for the imaging unit which has/have obtained thesaturated image or images, and image saturation can be prevented for atleast the imaging unit designated as the new main imaging unit.

“Image saturation” refers to a state wherein a portion or the entire ofan image is too bright or too dark so that no gradation can be expressedtherein. More specifically, the state of “image saturation” refers to astate wherein white compression is observed in an image due to luminancethereof becomes a predetermined threshold value or higher on a highluminance side, or a state wherein black compression occurs in an imagedue to luminance thereof becomes a predetermined threshold value orlower on a low luminance side, or a state wherein at least one of colorsignals comprising an image becomes a predetermined threshold value orlarger or a predetermined threshold value or smaller.

In the first multiple lens imaging apparatus of the present invention,in the case where the number of the sub-imaging unit having obtained thesaturated image or images is one, the exposure setting unit maydesignate the sub-imaging unit as the new main imaging unit.

In addition, in the case where the number of the sub-imaging unit havingobtained the saturated image or images is larger than one in the firstmultiple lens imaging apparatus of the present invention, the exposuresetting unit may designate the sub-imaging unit that has obtained theimage having a largest saturated region as the new main imaging unit.

A second multiple lens imaging apparatus of the present invention is amultiple lens imaging apparatus having a plurality of imaging unit forobtaining images by photography, and the apparatus comprises:

exposure setting unit for using an exposure value calculated accordingto a result of photometric measurement for predetermined main imagingunit among the plurality of imaging unit, to set exposure of the mainimaging unit and sub-imaging unit other than the main imaging unit. Inthe case where the number of the sub-imaging unit having obtainedsaturated images in photography by setting the exposure thereofaccording to the exposure value is larger than one, if the saturatedimages include an image saturated on a high luminance side and an imagesaturated on a low luminance side, the exposure setting unit calculatesthe exposure value separately for the sub-imaging unit having obtainedthe image saturated on the high luminance side and for the sub-imagingunit having obtained the image saturated on the low luminance side.

In this manner, the exposure value can be calculated so as not to causeimage saturation, for the imaging unit having obtained the imagesaturated on the high luminance side and for the imaging unit havingobtained the image saturated on the low luminance side. Therefore, imagesaturation can be prevented for at least the imaging unit havingobtained the saturated images.

A third multiple lens imaging apparatus of the present invention is amultiple lens imaging apparatus having a plurality of imaging unit forobtaining images by photography, and the apparatus comprises:

exposure setting unit for using an exposure value calculated accordingto a result of photometric measurement for predetermined main imagingunit among the plurality of imaging unit, to set exposure of the mainimaging unit and sub-imaging unit other than the main imaging unit. Inthe case where an image or images obtained in photography with thesub-imaging unit by setting the exposure thereof according to theexposure value is/are saturated, the exposure setting unit carries outjudgment as to whether a size of a saturated region therein is equal toor larger than a predetermined threshold value. In the case where aresult of the judgment is affirmative, the exposure setting unitcalculates the exposure value separately for the sub-imaging unit havingobtained the corresponding saturated image. In the case where the resultof the judgment is negative, the exposure setting unit designates anyone of the sub-imaging unit having obtained the saturated image_orimages as new main imaging unit. The exposure setting unit newlycalculates the exposure value and sets the exposure of the new mainimaging unit and new sub-imaging unit other than the new main imagingunit.

If the exposure value is calculated by designating as the new mainimaging unit the imaging unit that has obtained the image having thesaturated region whose size is equal to or larger than the predeterminedthreshold value, an amount of change in the exposure becomes large.Therefore, an image obtained by the new sub-imaging unit has a higherpossibility of image saturation. According to the third multiple lensimaging apparatus of the present invention, the exposure value iscalculated separately for the sub-imaging unit that has obtained theimage having the saturated region whose size is equal to or larger thanthe predetermined threshold value. Therefore, the exposure value can becalculated so as not to cause image saturation, and image saturation canbe prevented for at least the imaging unit that has obtained the imagehaving the saturated region whose size is equal to or larger than thepredetermined threshold value.

A fourth multiple lens imaging apparatus of the present invention is amultiple lens imaging apparatus having a plurality of imaging unit forobtaining images by photography, and the apparatus comprises:

exposure setting unit for using an exposure value calculated from aresult of photometric measurement according to a predeterminedphotometric method for predetermined main imaging unit among theplurality of imaging unit, to set exposure of the main imaging unit andsub-imaging unit other than the main imaging unit. In the case where animage or images obtained in photography with the sub-imaging unit bysetting the exposure thereof according to the exposure value is/aresaturated, the exposure setting unit calculates the exposure value againby changing the photometric method for the main imaging unit.

In this manner, the exposure value can be calculated according to adifferent photometric method. Therefore, by obtaining an image or imagesafter setting the exposure of the sub-imaging unit again according tothe re-calculated exposure value, judgment can be made again as towhether the image or images is/are saturated.

A fifth multiple lens imaging apparatus of the present invention is amultiple lens imaging apparatus having a plurality of imaging unit forobtaining images by photography, and the apparatus comprises:

exposure setting unit for using an exposure value calculated from aresult of photometric measurement according to a predeterminedphotometric method for predetermined main imaging unit among theplurality of imaging unit, to set exposure of the main imaging unit andsub-imaging unit other than the main imaging unit. In the case where animage or images obtained in photography with the sub-imaging unit bysetting the exposure thereof according to the exposure value is/aresaturated, the exposure setting unit designates any one of thesub-imaging unit having obtained the saturated image or images as newmain imaging unit, and calculates a new exposure value based on a resultof photometric measurement for the new main imaging unit according to aphotometric method that is different from the predetermined photometricmethod.

In this manner, the exposure value can be calculated according to adifferent photometric method for the new main imaging unit. Therefore,an image or images can be obtained by setting again the exposure of newsub-imaging unit according to the re-calculated exposure value, andjudgment as to whether the image or images is/are saturated can becarried out again.

In the first to fifth multiple lens imaging apparatuses of the presentinvention, the exposure setting unit may carry out judgment as towhether a saturated region in each of the images obtained by theplurality of imaging unit is within a predetermined region therein. Inthe case where a result of the judgment is affirmative, the exposuresetting unit judges that the corresponding image is saturated.

In the first to fifth multiple lens imaging apparatuses of the presentinvention, the exposure setting unit may carry out the judgment as towhether the image or images is/are saturated, in a predetermined regionin each of the images obtained by the plurality of imaging unit.

Each of the first to fifth multiple lens imaging apparatuses of thepresent invention may comprise a plurality of auxiliary light sourcescorresponding respectively to the plurality of imaging unit for emittingauxiliary lights to directions of photography by the correspondingimaging unit. In this case, each of the apparatuses may furthercomprise:

lighting control unit for controlling, in the case where the image orimages obtained in photography with the sub-imaging unit by setting theexposure thereof according to the exposure value is/are saturated,lighting on and off the auxiliary light sources depending on whether theimage or each of the images is saturated on a high luminance side or ona low luminance side.

More specifically, in the case where the image obtained by any one ofthe sub-imaging unit is saturated on a high luminance side, the lightingcontrol unit turns on the auxiliary light source corresponding to themain imaging unit so as to cause the image obtained by the main imagingunit to be brighter. In the case where the image obtained by any one ofthe sub-imaging unit is saturated on a low luminance side, the lightingcontrol unit turns on the auxiliary light source of the correspondingsub-imaging unit so as to cause the image obtained by the sub-imagingunit to become brighter. In the case where the images obtained by morethan one of the sub-imaging unit are saturated on the low luminanceside, the lighting control unit turns on the auxiliary light sources forall the sub-imaging unit having obtained the saturated images.

In this manner, a difference in brightness of a subject photographed bythe main imaging unit and the sub-imaging unit can be reduced.Therefore, the exposure can be set more easily.

A first exposure setting method of the present invention is an exposuresetting method for a multiple lens imaging apparatus having a pluralityof imaging unit for obtaining images by photography, and the methodcomprises the steps of:

carrying out judgment, at the time of using an exposure value calculatedaccording to a result of photometric measurement for predetermined mainimaging unit among the plurality of imaging unit to set exposure of themain imaging unit and sub-imaging unit other than the main imaging unit,as to whether an image or images obtained in photography with thesub-imaging unit by setting the exposure thereof according to theexposure value is/are saturated;

designating any one of the sub-imaging unit having obtained thesaturated image or images as new main imaging unit in the case where aresult of the judgment is affirmative; and

newly carrying out calculation of the exposure value and setting of theexposure of the new main imaging unit and new sub-imaging unit otherthan the new main imaging unit.

A second exposure setting method of the present invention is an exposuresetting method for a multiple lens imaging apparatus having a pluralityof imaging unit for obtaining images by photography, and the methodcomprises the steps of:

carrying out judgment, at the time of using an exposure value calculatedaccording to a result of photometric measurement for predetermined mainimaging unit among the plurality of imaging unit to set exposure of themain imaging unit and sub-imaging unit other than the main imaging unit,as to whether the number of the sub-imaging unit having obtainedsaturated images in photography by setting the exposure thereofaccording to the exposure value is larger than one; and,

in the case where a result of the judgment is affirmative and thesaturated images include an image saturated on a high luminance side andan image saturated on a low luminance side, calculating the exposurevalue separately for the sub-imaging unit having obtained the imagesaturated on the high luminance side and for the sub-imaging unit havingobtained the image saturated on the low luminance side.

A third exposure setting method of the present invention is an exposuresetting method for a multiple lens imaging apparatus having a pluralityof imaging unit for obtaining images by photography, and the methodcomprises the steps of:

carrying out judgment, at the time of using an exposure value calculatedaccording to a result of photometric measurement for predetermined mainimaging unit among the plurality of imaging unit to set exposure of themain imaging unit and sub-imaging unit other than the main imaging unit,as to whether an image or images obtained in photography with thesub-imaging unit by setting the exposure thereof according to theexposure value is/are saturated;

carrying out judgment, in the case where a result of the immediatelypreceding judgment is affirmative, as to whether a size of a saturatedregion therein is equal to or larger than a predetermined thresholdvalue;

calculating, in the case where a result of the immediately precedingjudgment is affirmative, the exposure value separately for thesub-imaging unit having obtained the corresponding saturated image;

designating, in the case where the result of the immediately precedingjudgment is negative, any one of the sub-imaging unit having obtainedthe saturated image or images as new main imaging unit; and

newly carrying out calculation of the exposure value and setting of theexposure of the new main imaging unit and new sub-imaging unit otherthan the new main imaging unit.

A fourth exposure setting method of the present invention is an exposuresetting method for a multiple lens imaging apparatus having a pluralityof imaging unit for obtaining images by photography, and the methodcomprises the steps of:

carrying out judgment, at the time of using an exposure value calculatedfrom a result of photometric measurement according to a predeterminedphotometric method for predetermined main imaging unit among theplurality of imaging unit to set exposure of the main imaging unit andsub-imaging unit other than the main imaging unit, as to whether animage or images obtained in photography with the sub-imaging unit bysetting the exposure thereof according to the exposure value is/aresaturated; and

calculating the exposure value again by changing the photometric methodfor the main imaging unit in the case where a result of the judgment isaffirmative.

A fifth exposure setting method of the present invention is an exposuresetting method for a multiple lens imaging apparatus having a pluralityof imaging unit for obtaining images by photography, and the methodcomprises the steps of:

carrying out judgment, at the time of using an exposure value calculatedfrom a result of photometric measurement according to a predeterminedphotometric method for predetermined main imaging unit among theplurality of imaging unit to set exposure of the main imaging unit andsub-imaging unit other than the main imaging unit, as to whether animage or images obtained in photography with the sub-imaging unit bysetting the exposure thereof according to the exposure value is/aresaturated; and

designating, in the case where a result of the judgment is affirmative,any one of the sub-imaging unit having obtained the saturated image orimages as new main imaging unit and calculating a new exposure valuebased on a result of photometric measurement for the new main imagingunit according to a photometric method that is different from thepredetermined photometric method.

The first to fifth exposure setting methods of the present invention maybe provided as programs that cause a computer to execute the methods.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows the configuration of a multiple lens imaging apparatus of afirst embodiment of the present invention;

FIG. 2 is a flow chart showing exposure setting processing in the firstembodiment;

FIG. 3 shows a situation of photography by imaging units;

FIGS. 4A and 4B show images obtained by the imaging units;

FIG. 5 shows profiles of luminance values in a horizontal direction ofthe images;

FIG. 6 shows the configuration of a multiple lens imaging apparatus of asecond embodiment of the present invention;

FIG. 7 is a flow chart showing exposure setting processing in the secondembodiment;

FIG. 8 is a flow chart showing exposure setting processing in a thirdembodiment;

FIGS. 9A and 9B show regions that are common among field angles ofimaging units;

FIG. 10 is a flow chart showing exposure setting processing in a fourthembodiment;

FIG. 11 is a flow chart showing exposure setting processing in a fifthembodiment;

FIG. 12 is a flow chart showing exposure setting processing in a sixthembodiment;

FIG. 13 shows the configuration of a multiple lens imaging apparatus ofa seventh embodiment of the present invention; and

FIG. 14 is a flow chart showing exposure setting processing in theseventh embodiment.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

Hereinafter, embodiments of the present invention will be described withreference to the accompanying drawings. FIG. 1 shows the configurationof a multiple lens imaging apparatus of a first embodiment of thepresent invention. A multiple lens imaging apparatus 1 shown in FIG. 1is used for generating a stereo image after obtaining two images havinga parallax by photography of the same subject with two spaced imagingunits 2A and 2B. Alternatively, the multiple lens imaging apparatus maybe used for generating a panoramic image from images obtained by the twoimaging units 2A and 2B located in parallel to each other. The imagesobtained by the two imaging units 2A and 2B may be still images ormoving images. In the embodiments described below, the images refer tostill images.

The imaging units 2A and 2B comprise lenses 10A and 10B, shutters 11Aand 11B, irises 12A and 12B, optical filters 13A and 13B, CCDs 14A and14B, shutter driving units 16A and 16B, iris driving units 17A and 17B,analog signal processing units 18A and 18B, and A/D conversion units 19Aand 19B.

The shutters 11A and 11B are mechanical shutters, and driven by theshutter driving units 16A and 16B each comprising a motor and a motordriver. The shutter driving units 16A and 16B control opening andclosing of the shutters 11A and 11B based on a signal generated bypressing a shutter release button and shutter speed data outputted froman AE/AWB processing unit 21 that will be described later.

The irises 12A and 12B are driven by the iris driving units 17A and 17Beach comprising a motor and a motor driver. Each of the iris drivingunits 17A and 17B adjusts an iris diameter based on iris value dataoutputted from the AE/AWB processing unit 21.

Each of the optical filters 13A and 13B is formed by RGB color filtersarranged regularly.

Each of the CCDs 14A and 14B has a photoelectric surface in which aplurality of light receiving elements are laid out two dimensionally. Alight from the subject forms an image on the photoelectric surface andsubjected to photoelectric conversion to obtain an analog image signal.

The analog image signal from each of the CCDs 14A and 14B is inputted toa corresponding one of the analog signal processing units 18A and 18B.Each of the analog signal processing units 18A and 18B comprises acorrelated double sampling circuit (CDS) that removes noise from theanalog signal, and an automatic gain controller (AGC) that adjusts again of the analog signal.

The analog signal processed by each of the analog signal processingunits 18A and 18B is inputted to a corresponding one of the A/Dconversion units 19A and 19B, and converted into a digital signal. Imagedata converted into the digital signal are CCD-RAW data having RGBdensity values for each of pixels.

The multiple lens imaging apparatus 1 also has an AF processing unit 20,the AE/AWB processing unit 21, an image processing unit 22, acompression/decompression unit 23, a media control unit 24, an internalmemory 26, an exposure setting unit 27, an operation unit 28, and a CPU30.

The AF processing unit 20 and the AE/AWB processing unit 21 determinephotography conditions based on a preliminary image. The preliminaryimage is an image represented by image data obtained as a result ofpreliminary photography with each of the CCDs 14A and 14B instructed bythe CPU 30 that has detected a half-press signal generated by half-pressof the shutter release button.

The AF processing unit 20 carries out AF processing by detecting a focalposition based on the preliminary image. As a method of detecting thefocal position, a passive method may be adopted, for example. A passivemethod detects an in-focus position by using a characteristic that animage has high contrast in a state of in-focus on a desired subject.

The AE/AWB processing unit 21 carries out measurement of luminance ofthe subject (photometric measurement) based on the preliminary image,and determines an iris value, a shutter speed, and the like based on themeasured luminance. The AE/AWB processing unit 21 calculates the irisvalue data and the shutter speed data as an exposure value (AEprocessing), and automatically adjusts white balance at the time ofphotography (AWB processing).

The image processing unit 22 carries out image quality enhancementprocessing such as gradation correction, sharpness correction, and colorcorrection on data of a final image. The image processing unit 22 alsocarries out YC processing to convert the CCD-RAW data into YC datacomprising Y data as a luminance signal, Cb data as a blue colordifference signal, and Cr data as a red color difference signal. Thefinal image is an image represented by image data inputted from each ofthe CCDs 14A and 14B, in actual photography carried out by full press ofthe shutter release button.

The compression/decompression unit 23 carries out compression processingin a format such as JPEG or motion JPEG on the final image data havingbeen subjected to the quality enhancement processing and the conversionby the image processing unit 22, and generates an image file. A tagstoring accompanying information such as time and date of photography isadded to the image file according to the Exif format or the like.

The media control unit 24 controls image-file reading and writing byaccessing a recording medium 25.

The internal memory 26 stores various kinds of constants set in themultiple lens imaging apparatus 1, a program executed by the CPU 30, andthe like.

The exposure setting unit 27 sets exposure of the two imaging units 2Aand 2B. More specifically, the exposure setting unit 27 predeterminesthe imaging unit 2A as a main imaging unit among the imaging units 2Aand 2B, and calculates the exposure value based on the preliminary imageobtained by the main imaging unit. The exposure setting unit 27basically sets the exposure of the imaging unit 2B (a sub-imaging unit)and the main imaging unit 2A, based on the calculated exposure value.Details of this processing by the exposure setting unit 27 will bedescribed later.

The CPU 30 controls each of the units of the multiple lens imagingapparatus 1 according to a signal from each of the processing units suchas the AE/AWB processing unit 21 and the operation unit 28 including theshutter release button.

A data bus 31 is connected to the A/D conversion units 19A and 19B, theAF processing unit 20, the AE/AWB processing unit 21, the imageprocessing unit 22, the compression/decompression unit 23, the mediacontrol unit 24, the internal memory 26, the exposure setting unit 27,and the CPU 30, for exchange of the digital image data and the like.

The exposure setting processing carried out by the exposure setting unit27 will be described next. FIG. 2 is a flow chart showing the exposuresetting processing in the first embodiment. When a photographerinstructs the start of photography by using the operation unit 28, theCPU 30 starts the processing. The exposure setting unit 27 instructs themain imaging unit 2A to obtain the preliminary image, and the mainimaging unit 2A obtains the preliminary image (Step ST1). The AE/AWBprocessing unit 21 carries out the AE processing by using thepreliminary image, and calculates the exposure value (Step ST2). Theexposure setting unit 27 sets the exposure of the main imaging unit 2Aand the sub-imaging unit 2B, based on the calculated exposure value(Step ST3).

The exposure setting unit 27 then instructs the sub-imaging unit 2Bwhose exposure has been set to obtain the preliminary image, and thesub-imaging unit 2B obtains the preliminary image (Step ST4). Theexposure setting unit 27 judges whether the preliminary image issaturated (Step ST5). More specifically, the exposure setting unit 27judges whether the preliminary image includes a region wherein whitecompression and/or black compression is observed.

For judgment of white compression, the exposure setting unit 27calculates luminance values for all the pixels in the preliminary image,and judges that the preliminary image includes a region wherein whitecompression is observed (hereinafter referred to as a white compressionregion) in the case where any portion of the calculated luminance valuesis equal to or larger than a threshold value Th1 determined withreference to a highest luminance value that the preliminary image cantake. The threshold value Th1 is a value that is approximately 97% ofthe highest luminance value. For example, the threshold value Th1 is 247in the case where the highest luminance value is 8-bit (that is, 255).

For judgment of black compression, the exposure setting unit 27calculates the luminance values for all the pixels in the preliminaryimage, and judges that the preliminary image includes a region whereinblack compression is observed (hereinafter referred to as a blackcompression region) in the case where any portion of the calculatedluminance values is equal to or smaller than a threshold value Th2determined with reference to a lowest luminance value that thepreliminary image can take. The threshold value Th2 is a value that isapproximately 3% of the highest luminance value. For example, thethreshold value Th2 is 7 in the case where the highest luminance valueis 8-bit (that is, 255).

If a result of the judgment at Step ST5 is affirmative, the exposuresetting unit 27 designates the sub-imaging unit 2B as a new main imagingunit (Step ST6), and the processing returns to Step ST1. In this manner,the procedures after Step ST1 are repeated by using the new main imagingunit 2B.

In the case where the result of the judgment at Step ST5 is negative,the exposure setting unit 27 instructs the imaging units 2A and 2B tocarry out actual photography by setting the exposure according to theexposure value having been calculated. In response, the imaging units 2Aand 2B carry out the actual photography (Step ST7). Two image data setsobtained in the actual photography are recorded in the recording medium25 (Step ST8) to end the processing.

FIG. 3 shows a situation of photography by the imaging units 2A and 2B.As shown in FIG. 3, in the case where a subject 40 is photographed bythe imaging units 2A and 2B, assume that a sun 41 is located above theright of the subject 40. In this situation, an image G1 shown in FIG. 4Ais obtained by the imaging unit 2A while an image G2 shown in FIG. 4B isobtained by the imaging unit 2B. When the images G1 and G2 are comparedto each other, the sun 41 is included in a field angle of the imagingunit 2B. Therefore, the image G2 includes a high luminance regioncorresponding to the sun 41.

FIG. 5 shows profiles of the luminance values in a horizontal directionof the images G1 and G2. The profiles shown in FIG. 5 correspond to theposition of the sun 41 in the image G2. In FIG. 5, A1 refers to a fieldangle of the imaging unit 2A, and A2 refers to the field angle of theimaging unit 2B. A profile P1 is a profile of the luminance valuesbefore setting the exposure while a profile P2 is a profile of theluminance values after the exposure has been set. The imaging unit 2Ahas obtained the image in a range corresponding to the field angle A1,and the luminance values have become high as shown by the profile P2 asa result of exposure setting by calculation of the exposure value basedon the image in the range of field angle A1.

In this case, if the exposure is set for the imaging unit 2B based onthe exposure value having been calculated, the luminance values of theimage obtained by the imaging unit 2B become high as by the imaging unit2A. Therefore, a portion of the luminance values corresponding to thesun 41 becomes higher. As a result, the luminance values correspondingto the sun 41 are larger than the threshold value Th1, causing whitecompression in the image. In this case, the imaging unit 2B isdesignated as the new main imaging unit in the first embodiment, and theexposure value is calculated based on the image obtained by the new mainimaging unit. In this manner, the exposure value that does not causeimage saturation as much as possible can be calculated again for theimaging units 2A and 2B.

A second embodiment of the present invention will be described next.FIG. 6 shows the configuration of a multiple lens imaging apparatus inthe second embodiment. In the second embodiment, the same elements as inthe first embodiment have the same reference codes, and detaileddescription thereof will be omitted. A multiple lens imaging apparatus1A in the second embodiment further comprises a third imaging unit 2C,in addition to the two imaging units 2A and 2B. The exposure settingunit 27 carries out different processing from the processing in thefirst embodiment.

FIG. 7 is a flow chart showing exposure setting processing in the secondembodiment. When a photographer instructs the start of photography byusing the operation unit 28, the CPU 30 starts the processing. Theexposure setting unit 27 instructs the main imaging unit 2A to obtainthe preliminary image, and the main imaging unit 2A obtains thepreliminary image (Step ST11). The AE/AWB processing unit 21 carries outthe AE processing by using the preliminary image, and calculates theexposure value (Step ST12). The exposure setting unit 27 sets theexposure of the main imaging unit 2A and the sub-imaging units 2B and2C, based on the calculated exposure value (Step ST13).

The exposure setting unit 27 then instructs the sub-imaging units 2B and2C whose exposure has been set to obtain the preliminary images, and thesub-imaging units 2B and 2C obtain the preliminary images (Step ST14).The exposure setting unit 27 judges whether the preliminary images aresaturated (Step ST15).

If the result of judgment at Step ST15 is affirmative, the exposuresetting unit 27 judges whether the number of the saturated preliminaryimages is larger than one (Step ST16). If the result of judgment at StepST16 is negative, only one of the preliminary images is saturated.Therefore, the exposure setting unit 27 designates the sub-imaging unitthat has obtained the saturated preliminary image as a new main imagingunit (Step ST17), and the processing returns to Step ST11. In thismanner, the procedures after Step ST11 are repeated by using the newmain imaging unit.

In the case where the result at Step ST16 is affirmative, the exposuresetting unit 27 calculates an area of a saturated region in each of thesaturated preliminary images (Step ST18), and designates the sub-imagingunit that has obtained the preliminary image having a largest saturatedregion as the new main imaging unit (Step ST19). The processing thenreturns to Step ST11.

In the case where the result of the judgment at Step ST15 is negative,the exposure setting unit 27 instructs the imaging units 2A, 2B and 2Cto carry out actual photography by setting the exposure according to theexposure value having been calculated. In response, the imaging units2A, 2B and 2C carry out the actual photography (Step ST20). Three imagedata sets obtained in the actual photography are recorded in therecording medium 25 (Step ST21) to end the processing.

In the second embodiment, the number of the imaging units is three.However, the processing can be carried out in the same manner for thecase where the number of the imaging units is four or more.

A third embodiment of the present invention will be described next. Amultiple lens imaging apparatus in the third embodiment has the sameconfiguration as the multiple lens imaging apparatus 1A in the secondembodiment, and processing carried out by the exposure setting unit 27is solely different. Therefore, detailed description of theconfiguration of the apparatus will be omitted.

FIG. 8 is a flow chart showing exposure setting processing in the thirdembodiment. When a photographer instructs the start of photography byusing the operation unit 28, the CPU 30 starts the processing. Theexposure setting unit 27 instructs the main imaging unit 2A to obtainthe preliminary image, and the main imaging unit 2A obtains thepreliminary image (Step ST31). The AE/AWB processing unit 21 carries outthe AE processing by using the preliminary image, and calculates theexposure value (Step ST32). The exposure setting unit 27 sets theexposure of the main imaging unit 2A and the sub-imaging units 2B and2C, based on the calculated exposure value (Step ST33).

The exposure setting unit 27 then instructs the sub-imaging units 2B and2C whose exposure has been set to obtain the preliminary images, and thesub-imaging units 2B and 2C obtain the preliminary images (Step ST34).The exposure setting unit 27 judges whether the preliminary images aresaturated (Step ST35).

If the result of judgment at Step ST35 is affirmative, the exposuresetting unit 27 judges whether the number of the saturated preliminaryimages is larger than one (Step ST36). If the result of judgment at StepST36 is negative, only one of the preliminary images is saturated.Therefore, the exposure setting unit 27 designates the sub-imaging unithaving obtained the saturated preliminary image as a new main imagingunit (Step ST37), and the processing returns to Step ST31. In thismanner, the procedures after Step ST31 are repeated by using the newmain imaging unit.

If the result of judgment at Step ST36 is affirmative, the exposuresetting unit 27 judges whether the number of the saturated preliminaryimages including a white compression region is one or larger and whetherthe number of the saturated preliminary images including a blackcompression region is one or larger (Step ST38). If results at Step ST38are both affirmative, the exposure setting unit 27 calculates theexposure value separately for each of the sub-imaging units 2B and 2C(Step ST39). If the results at Step ST38 are not both affirmative, theexposure setting unit 27 calculates an area of each saturated region inthe saturated preliminary images (Step ST40), and designates thesub-imaging unit that has obtained the preliminary image having alargest area of saturation as a new main imaging unit (Step ST41). Theprocessing then returns to Step ST31.

Following Step ST39 and in the case where the result at Step ST35 isnegative, the exposure setting unit 27 instructs the imaging units 2A to2C to carry out actual photography by setting the exposure according tothe calculated exposure value, and the imaging units 2A to 2C carry outthe actual photography (Step ST42). Three image data sets obtained inthe actual photography are then recorded in the recording medium 25(Step ST43) to end the processing.

In the third embodiment, the number of the imaging units is three.However, the processing can be carried out in the same manner for thecase where the number of the imaging units is four or more.

In the case where a stereo image is generated, not the entire regions ofrespective images obtained by imaging units are used but only regionsthat are common among field angles of the imaging units are used. Inother words, in generation of a stereo image, only the regions that arecommon among the field angles of the imaging units have to be inappropriate luminance. For example, in the images G1 and G2 shown inFIGS. 4A and 4B, if regions A11 and A12 in the images G1 and G2 arecommon among the field angles of the imaging units 2A and 2B as shown inFIGS. 9A and 9B, the images have to be in appropriate luminance only inthe regions A11 and A12. Therefore, in the case where the saturatedregion or regions in the preliminary image or images obtained by thesub-imaging unit or units in the first to third embodiments is/are notin the region or regions necessary for generation of a stereo image, theexposure therefor does not need to be set again. Hereinafter, processingin consideration of this fact will be described as a fourth embodiment.

The regions necessary for generation of a stereo image can be calculatedbased on a method of calculation according to positions and orientationsof the imaging units 2A and 2B, or based on a method of calculationaccording to images obtained in advance by the imaging units 2A and 2B,for example. In the former case, if the imaging units 2A and 2B arecontrolled in such a manner that the positions and the orientationsthereof are movable, the regions necessary for generation of a stereoimage may be calculated based on a result of the control. In the lattercase, if moving images are photographed especially, each of the regionsnecessary for generation of a stereo image may be calculated based on animmediately preceding frame.

FIG. 10 is a flow chart showing exposure setting processing in thefourth embodiment. The flow chart in FIG. 10 is to judge whether asaturated region in the preliminary image obtained by the sub-imagingunit in the first embodiment is within the region necessary forgeneration of a stereo image. However, the processing can be applied tothe second and third embodiments in the same manner.

When a photographer instructs the start of photography by using theoperation unit 28, the CPU 30 starts the processing. The exposuresetting unit 27 instructs the main imaging unit 2A to obtain thepreliminary image, and the main imaging unit 2A obtains the preliminaryimage (Step ST51). The AE/AWB processing unit 21 carries out the AEprocessing by using the preliminary image, and calculates the exposurevalue (Step ST52). The exposure setting unit 27 sets the exposure of themain imaging unit 2A and the sub-imaging unit 2B, based on thecalculated exposure value (Step ST53).

The exposure setting unit 27 then instructs the sub-imaging unit 2Bwhose exposure has been set to obtain the preliminary image, and thesub-imaging unit 2B obtains the preliminary image (Step ST54). Theexposure setting unit 27 judges whether the preliminary image issaturated (Step ST55).

If the result of judgment at Step ST55 is affirmative, the exposuresetting unit 27 judges whether a saturated region is in the regionnecessary for generation of a stereo image (Step ST56). If the result ofjudgment at Step ST56 is affirmative, the exposure setting unit 27designates the sub-imaging unit 2B as a new main imaging unit (StepST57), and the processing returns to Step ST51. In this manner, theprocedures from Step ST51 are repeated with the imaging unit 2Bdesignated as the new main imaging unit.

If the results at Steps ST55 and ST56 are negative, the exposure settingunit 27 instructs the imaging units 2A and 2B to carry out actualphotography by setting the exposure according to the exposure valuehaving been calculated, and the imaging units 2A and 2B carry out theactual photography (Step ST58). Two image data sets obtained in theactual photography are recorded in the recording medium 25 (Step ST59),to end the processing.

In the fourth embodiment described above, whether the saturated regionis in the region necessary for generation of a stereo image is judged inthe case of the preliminary image being saturated. However, the regionsnecessary for generation of a stereo image are predetermined. Therefore,the judgment as to whether the preliminary images in the first to thirdembodiments are saturated may be carried out only on the regionsnecessary for generation of a stereo image.

A fifth embodiment of the present invention will be described next. Amultiple lens imaging apparatus in the fifth embodiment has the sameconfiguration as the multiple lens imaging apparatus 1 in the firstembodiment, and processing by the exposure setting unit 27 is solelydifferent. Therefore, detailed description of the configuration of theapparatus will be omitted. In the case where white compression isobserved in the image or images obtained by the sub-imaging unit orunits in the first to fourth embodiments described above and theluminance varies greatly between the image obtained by the main imagingunit and the image or images obtained by the sub-imaging unit or units,black compression may be observed in the image or images obtained by thenew sub-imaging unit or units if the exposure value is calculated bydesignating the sub-imaging unit or one of the sub-imaging units as thenew main imaging unit. The fifth embodiment is to solve this problem.

FIG. 11 is a flow chart showing exposure setting processing in the fifthembodiment. When a photographer instructs the start of photography byusing the operation unit 28, the CPU 30 starts the processing. Theexposure setting unit 27 instructs the main imaging unit 2A to obtainthe preliminary image, and the main imaging unit 2A obtains thepreliminary image (Step ST61). The AE/AWB processing unit 21 carries outthe AE processing by using the preliminary image, and calculates theexposure value (Step ST62). The exposure setting unit 27 sets theexposure of the main imaging unit 2A and the sub-imaging unit 2B, basedon the calculated exposure value (Step ST63).

The exposure setting unit 27 then instructs the sub-imaging unit 2Bwhose exposure has been set to obtain the preliminary image, and thesub-imaging unit 2B obtains the preliminary image (Step ST64). Theexposure setting unit 27 judges whether the preliminary image issaturated (Step ST65). At this time, the judgment may be carried outonly on the region necessary for generation of a stereo image.

If the result of judgment at Step ST65 is affirmative, the exposuresetting unit 27 judges whether an area of a saturated region is apredetermined threshold value Th3 or larger (Step ST66). If the resultat Step ST65 is affirmative, the judgment as to whether the saturatedregion is within the region necessary for generation of a stereo imagemay be carried out as in the fourth embodiment. If the result ofjudgment at Step ST66 is negative, the exposure setting unit 27designates the sub-imaging unit 2B as a new main imaging unit (StepST67), and the processing returns to Step ST61. In this manner, theprocedures from Step ST61 are repeated by using the imaging unit 2B asthe new main imaging unit.

If the result at Step ST66 is affirmative, the exposure setting unit 27calculates the exposure value separately for the sub-imaging unit 2B(Step ST68). In this manner, the exposure can be set so as not to causesaturation in the image obtained by the sub-imaging unit 2B.

After Step ST68 and in the case where the result at Step ST65 isnegative, the exposure setting unit 27 instructs the imaging units 2Aand 2B to carry out actual photography by setting the exposure accordingto the exposure value having been calculated. In response, the imagingunits 2A and 2B carry out the actual photography (Step ST69). Two imagedata sets obtained in the actual photography are recorded in therecording medium 25 (Step ST70) to end the processing.

In the case where a stereo image is generated, a center region of animage obtained by each of imaging units is used therefor. Consequently,in the case where the image or images obtained by the sub-imaging unitor units is/are saturated, it is preferable for a method of photometryto be changed to measure a center region of an image with emphasis.Hereinafter, processing in consideration of this point will be describedas a sixth embodiment.

FIG. 12 is a flow chart showing exposure setting processing in the sixthembodiment. The flow chart in FIG. 12 is to change a photometric methodin the first embodiment. However, the processing can be applied to thesecond to fifth embodiments in the same manner.

When a photographer instructs the start of photography by using theoperation unit 28, the CPU 30 starts the processing. The exposuresetting unit 27 instructs the main imaging unit 2A to obtain thepreliminary image, and the main imaging unit 2A obtains the preliminaryimage (Step ST81). The AE/AWB processing unit 21 carries out the AEprocessing by using the preliminary image, and calculates the exposurevalue (Step ST82). The exposure setting unit 27 sets the exposure of themain imaging unit 2A and the sub-imaging unit 2B, based on thecalculated exposure value (Step ST83).

The exposure setting unit 27 then instructs the sub-imaging unit 2Bwhose exposure has been set to obtain the preliminary image, and thesub-imaging unit 2B obtains the preliminary image (Step ST84). Theexposure setting unit 27 judges whether the preliminary image issaturated (Step ST85). At this time, the judgment may be carried outonly on the region necessary for generation of a stereo image.

If the result of judgment at Step ST85 is affirmative, the exposuresetting unit 27 then instructs the main imaging unit 2A and the AE/AWBprocessing unit 21 to calculate the exposure value by causing the mainimaging unit 2A to obtain the preliminary image after changing thephotometric method from a method of photometric measurement over theentire image to a method of photometric measurement with emphasis on acenter portion thereof, for example (Step ST86). The processing thenreturns to Step ST83, and the procedures after Step ST83 are repeated.If the result at Step ST85 is affirmative, whether a saturated region isthe region used for generation of a stereo image may be judged as in thefourth embodiment.

If the result at Step ST85 is negative, the exposure setting unit 27instructs the imaging units 2A and 2B to carry out actual photography bysetting the exposure according to the calculated exposure value, and theimaging units 2A and 2B carry out the actual photography (Step ST87).Two image data sets obtained in the actual photography are then recordedin the recording medium 25 (Step ST88) to end the processing.

In the sixth embodiment described above, the photometric method ischanged for the main imaging unit at Step ST86. However, the exposuresetting unit 27 may designate the sub-imaging unit as a new main imagingunit and the photometric method may be changed for the new main imagingunit.

A seventh embodiment of the present invention will be described next.FIG. 13 shows the configuration of a multiple lens imaging apparatus inthe seventh embodiment. In the seventh embodiment, the same elements asin the first embodiment have the same reference codes, and detaileddescription thereof will be omitted. A multiple lens imaging apparatus1B in the seventh embodiment is different from the first embodiment inthat the imaging units 2A and 2B comprise auxiliary light sources 50Aand 50B for emitting auxiliary lights to directions of photography bythe imaging units 2A and 2B, and the apparatus comprises a lightingcontrol unit 51 for controlling light emission from the auxiliary lightsources 50A and 50B.

The auxiliary light sources may be LEDs, for example. Alternatively,flashes may be used instead of LEDs.

The lighting control unit 51 controls light emission from the auxiliarylight sources 50A and 50B, according to whether the preliminary imageobtained by the sub-imaging unit 2B is saturated on a high luminanceside or on a low luminance side. How the light emission is controlledwill be described later.

FIG. 14 is a flow chart showing exposure setting processing in theseventh embodiment. When a photographer instructs the start ofphotography by using the operation unit 28, the CPU 30 starts theprocessing. The exposure setting unit 27 instructs the main imaging unit2A to obtain the preliminary image, and the main imaging unit 2A obtainsthe preliminary image (Step ST91). The AE/AWB processing unit 21 carriesout the AE processing by using the preliminary image, and calculates theexposure value (Step ST92). The exposure setting unit 27 sets theexposure of the main imaging unit 2A and the sub-imaging unit 2B, basedon the calculated exposure value (Step ST93).

The exposure setting unit 27 then instructs the sub-imaging unit 2Bwhose exposure has been set to obtain the preliminary image, and thesub-imaging unit 2B obtains the preliminary image (Step ST94). Theexposure setting unit 27 judges whether the preliminary image issaturated (Step ST95).

If the result of judgment at Step ST95 is affirmative, the exposuresetting unit 27 designates the sub-imaging unit 2B as a new main imagingunit (Step ST96), and the lighting control unit 51 controls the lightemission from the auxiliary light sources 50A and 50B according towhether the preliminary image is saturated on the high luminance side oron the low luminance side (Step ST97). The processing then returns toStep ST91. In this manner, the procedures from Step ST91 are repeated byusing the imaging unit 2B as the new main imaging unit.

For controlling the light emission from the auxiliary light sources, inthe case where the preliminary image obtained by the sub-imaging unit 2Bis saturated on the high luminance side and has a white compressionregion, only the auxiliary light source 50A for the main imaging unit 2Ais turned on so that the image obtained by the main imaging unit 2Abecomes brighter. In the case the preliminary image obtained by thesub-imaging unit 2B is saturated on the low luminance side and has ablack compression region, only the auxiliary light source 50B for thesub-imaging unit 2B is turned on so that the image obtained by thesub-imaging unit 2B becomes brighter.

If the result at Step ST95 is negative, the exposure setting unit 27instructs the imaging units 2A and 2B to carry out actual photography bysetting the exposure according to the exposure value having beencalculated, and the imaging units 2A and 2B carry out the actualphotography (Step ST98). Two image data sets obtained in the actualphotography are then recorded in the recording medium 25 (Step ST99) toend the processing.

In this manner, difference in brightness of the subject can be reducedbetween the images obtained by the main imaging unit and the sub-imagingunit in the seventh embodiment. Therefore, the exposure can be seteasily.

The seventh embodiment can be applied to the case where the number ofthe imaging units is three or more. In this case, if the preliminaryimages obtained by the sub-imaging units are saturated on a lowluminance side and have black compression regions, all the auxiliarylight sources for the sub-imaging units that have obtained the saturatedimages are turned on.

In the first to seventh embodiments described above, the cases of stillimage photography have been described. However, the exposure can be setin the same manner for moving images. In this case, the exposure valueis calculated for the main imaging unit based on one frame in a movingimage, instead of the preliminary image. In the case where one frameobtained by the sub-imaging unit after setting the exposure thereofaccording to the calculated exposure value is saturated, the sameprocessing as in the first to seventh embodiments is carried out.

In the first to seventh embodiments of the present invention, theimaging unit 2A is predetermined as the main imaging unit. However, inthe case where photography is carried out again after the main imagingunit has been changed in the immediately preceding photography, theexposure may be set by designating as the main imaging unit the imagingunit having been designated as the main imaging unit in the immediatelypreceding photography.

Although the multiple lens imaging apparatuses related to theembodiments of the present invention have been described above, programsthat cause a computer to function as means corresponding to the exposuresetting unit 27 and to execute the processing shown in FIGS. 2, 7, 8,10, 11, 12 and 14 are also embodiments of the present invention. Inaddition, computer-readable recording media storing such programs arealso embodiments of the present invention.

Note that the program of the present invention may be provided beingrecorded on a computer readable medium. Those who are skilled in the artwould know that computer readable media are not limited to any specifictype of device, and include, but are not limited to: CD's, RAM's ROM's,hard disks, magnetic tapes, and internet downloads, in which computerinstructions can be stored and/or transmitted. Transmission of thecomputer instructions through a network or through wireless transmissionmeans is also within the scope of this invention. Additionally, thecomputer instructions include, but are not limited to: source, object,and executable code, and can be in any language, including higher levellanguages, assembly language, and machine language.

While there has been described what are at present considered to bepreferred embodiments of the invention, it will be understood thatvarious modifications may be made thereto, and it is intended that theappended claims cover all such modifications as fall within the truespirit and scope of the invention.

1. A multiple lens imaging apparatus comprising: a plurality of imagingunit for obtaining images by photography; and exposure setting unit forusing an exposure value calculated according to a result of photometricmeasurement for predetermined main imaging unit among the plurality ofimaging unit, to set exposure of the main imaging unit and sub-imagingunit other than the main imaging unit, wherein, in the case where animage or images obtained in photography with the sub-imaging unit bysetting the exposure thereof according to the exposure value is/aresaturated, the exposure setting unit designates any one of thesub-imaging unit having obtained the saturated image or images as newmain imaging unit, and newly calculates the exposure value and sets theexposure of the new main imaging unit and new sub-imaging unit otherthan the new main imaging unit.
 2. The multiple lens imaging apparatusaccording to claim 1, wherein, in the case where the number of thesub-imaging unit having obtained the saturated image or images is one,the exposure setting unit designates the sub-imaging unit as the newmain imaging unit.
 3. The multiple lens imaging apparatus according toclaim 1, wherein, in the case where the number of the sub-imaging unithaving obtained the saturated image or images is larger than one, theexposure setting unit designates the sub-imaging unit having obtainedthe image with a largest saturated region therein as the new mainimaging unit.
 4. The multiple lens imaging apparatus according to claim1, wherein the exposure setting unit carries out judgment as to whethera saturated region in each of the images obtained by the plurality ofimaging unit is within a predetermined region therein, and, in the casewhere a result of the judgment is affirmative, the exposure setting unitjudges that the corresponding image is saturated.
 5. The multiple lensimaging apparatus according to claim 1, wherein, the exposure settingunit carries out the judgment as to whether the image or images is/aresaturated, in a predetermined region in each of the images obtained bythe plurality of imaging unit.
 6. The multiple lens imaging apparatusaccording to claim 1, the apparatus comprising: a plurality of auxiliarylight sources corresponding respectively to the plurality of imagingunit for emitting auxiliary lights to directions of photography by thecorresponding imaging unit; and the apparatus further comprising:lighting control unit for controlling, in the case where the image orimages obtained in photography with the sub-imaging unit by setting theexposure thereof according to the exposure value is/are saturated,lighting on and off the auxiliary light sources depending on whether theimage or each of the images is saturated on a high luminance side or ona low luminance side.
 7. An exposure setting method for a multiple lensimaging apparatus having a plurality of imaging unit for obtainingimages by photography, the method comprising the steps of: carrying outjudgment, at the time of using an exposure value calculated according toa result of photometric measurement for predetermined main imaging unitamong the plurality of imaging unit to set exposure of the main imagingunit and sub-imaging unit other than the main imaging unit, as towhether an image or images obtained in photography with the sub-imagingunit by setting the exposure thereof according to the exposure valueis/are saturated; designating, in the case where a result of thejudgment is affirmative, any one of the sub-imaging unit having obtainedthe saturated image or images as new main imaging unit; and newlycarrying out calculation of the exposure value and setting of theexposure of the new main imaging unit and new sub-imaging unit otherthan the new main imaging unit.
 8. An exposure setting method for amultiple lens imaging apparatus having a plurality of imaging unit forobtaining images by photography, the method comprising the steps of:carrying out judgment, at the time of using an exposure value calculatedfrom a result of photometric measurement according to a predeterminedphotometric method for predetermined main imaging unit among theplurality of imaging unit to set exposure of the main imaging unit andsub-imaging unit other than the main imaging unit, as to whether animage or images obtained in photography with the sub-imaging unit bysetting the exposure thereof according to the exposure value is/aresaturated; and designating, in the case where a result of the judgmentis affirmative, any one of the sub-imaging unit having obtained thesaturated image or images as new main imaging unit and calculating a newexposure value based on a result of photometric measurement for the newmain imaging unit according to a photometric method different from thepredetermined photometric method.
 9. A non-transitory computer-readablerecording medium storing a program causing a computer to execute anexposure setting method for a multiple lens imaging apparatus having aplurality of imaging unit for obtaining images by photography, theprogram comprising the procedures of: carrying out judgment, at the timeof using an exposure value calculated according to a result ofphotometric measurement for predetermined main imaging unit among theplurality of imaging unit to set exposure of the main imaging unit andsub-imaging unit other than the main imaging unit, as to whether animage or images obtained in photography with the sub-imaging unit bysetting the exposure thereof according to the exposure value is/aresaturated; designating, in the case where a result of the judgment isaffirmative, any one of the sub-imaging unit having obtained thesaturated image or images as new main imaging unit; and newly carryingout calculation of the exposure value and setting of the exposure of thenew main imaging unit and new sub-imaging unit other than the new mainimaging unit.
 10. A non-transitory computer-readable recording mediumstoring a program causing a computer to execute an exposure settingmethod for a multiple lens imaging apparatus having a plurality ofimaging unit for obtaining images by photography, the program comprisingthe procedures of: carrying out judgment, at the time of using anexposure value calculated from a result of photometric measurementaccording to a predetermined photometric method for predetermined mainimaging unit among the plurality of imaging unit to set exposure of themain imaging unit and sub-imaging unit other than the main imaging unit,as to whether an image or images obtained in photography with thesub-imaging unit by setting the exposure thereof according to theexposure value is/are saturated; and designating, in the case where aresult of the judgment is affirmative, any one of the sub-imaging unithaving obtained the saturated image or images as new main imaging unitand calculating a new exposure value based on a result of photometricmeasurement for the new main imaging unit according to a photometricmethod different from the predetermined photometric method.